JP3498056B2 - A wireless telephone that quickly reacquires a timing reference from a wireless network after sleep mode - Google Patents

Abstract

A method for rapidly reacquiring a timing reference after a sleep period in a wireless telephone receiving pilot signals from one or more base stations in a wireless network, wherein the wireless telephone has a master timer (local time reference), a fast, accurate clock source, a slow, less accurate but power efficient clock source and a memory. The method includes the steps of entering the sleep period by storing one or more parameters related to the pilot signals and how the pilot signals are changing over time, calculating a prediction of the parameters of the pilot signals after a sleep period based on the stored parameters, storing the prediction, starting the slow clock, and stopping the master timer (local time reference) and fast clock source. The method further includes the steps of ending the sleep period by generating a wake-up interrupt by the slow clock after the sleep period, restarting the master timer and fast clock source responsive to the wake-up interrupt, and reacquiring pilot signals using the predictions stored previously. A time correction factor can then be computed that closely aligns the received pilot signals on the prediction which is then weighted and the master timer is adjusted by the weighted time correction.

Description

Detailed Description of the Invention

FIELD OF THE INVENTION The present invention relates to a wireless telephone, after a sleep mode,
Re-acquisition of timing reference from wireless network.

BACKGROUND OF THE INVENTION The various goals of minimizing the size and weight of wireless phones (also called cell phones, mobile stations, or mobile phones) and the time during which they can be used without recharging the battery. There is a tension between and the amount of. In general,
The larger the battery capacity, the larger and heavier the battery. While many advances have been made in battery technology to address this problem, other areas of wireless telephone technology conserve battery energy and therefore wireless telephones between recharges. Efforts are underway to extend the uptime of the.

In direct spread spectrum, code division multiple access (CDMA) radio technology, there is a recognized need for battery energy conservation. For this purpose, IS
The 95 CDMA standard specifies a "sleep mode" in wireless phones, in which the power consuming components are turned off. When the wireless phone is idle (ie, not in a call and not receiving commands from the wireless system), the wireless phone is only receiving paging channels for commands or pages from the wireless system. . Paging messages for a particular wireless phone can occur in the range of once every 1.28 seconds to once every 163.84 seconds. Thus, the radiotelephone may turn off power to its many components at other times. This technique is a very powerful way to conserve battery energy when a battery-operated radiotelephone is idle.

However, problems occur when the components of the radiotelephone come out of sleep mode. As is known in the art, many wireless communication systems use a centralized time reference to maintain modulation and demodulation synchronization. Most radio telephones include an oscillator as a frequency reference and input the time reference to a master timer or local system. This oscillator is often a temperature compensated crystal oscillator that maintains accurate alignment of the radiotelephone clock with the system reference clock. Since the temperature compensated crystal oscillator uses a relatively large amount of power when operating, it is desirable to disable (power off) the temperature compensated crystal oscillator. However, to resume modulation and demodulation of the signal, the master timer (local time reference) must be resynchronized to the network time reference when the oscillator is brought back on. One method of resynchronization is to acquire the sync channel as in a wireless phone power-up routine. Such synchronization may take most of the sleep period. In the worst case, the acquisition of the sync channel may require more power than the master timer requires, if it stays powered on during the sleep period. GB-A-2,324,68
1 uses fine mode clock and coarse mode clock
The low power sleep mode that was
During the duration of the coarse mode clock (sleep clock) cycle
Interval occurs over an integer number of sleep mode clock periods.
Measured based on the number of fine mode clock periods
Used to track stem time. System time
Is calculated, and then using the calculated system time
The signal is reacquired upon exit from sleep mode
To be done. The present invention is directed to overcoming one or more of the problems set forth above.

SUMMARY OF THE INVENTION One feature of the invention is a wireless telephone receiving a pilot signal having multiple parameters from one or more base stations in a wireless network, timing after a sleep period. It discloses a method for quickly reacquiring the standard. This wireless phone
It has a local time reference (master timer) synchronized to a timing reference in the wireless network, a fast and accurate clock, a slow and less accurate but power efficient clock, and a memory. The method comprises storing one or more parameters of a pilot signal, calculating a prediction parameter of the pilot signal after the sleep period based on the stored parameters, and the prediction a master timer. Inward loading, starting a low speed clock source, and stopping the master timer (local time reference) and high speed clock source. The method further comprises generating a wake-up interrupt with the slow clock after the sleep period, restarting a master timer and a processor in response to the wake-up interrupt, and sending a pilot signal. Reacquiring. Next, a time correction factor that seems to best align the received pilot signal with the prediction is used to estimate the parameters of the received pilot signal.
Calculated based on multiple correlation . The master timer (local time reference) is adjusted by weighted time correction. Book
According to another feature of the invention, using a slide correlator
Multiple comparisons are performed and the master timer
By the time correction associated with the maximum correlation determined by the
Be adjusted. Furthermore, due to each correlation,
The id correlator estimates the received pilot signal samples to
Multiply the parameters to obtain the received pilot signal and the prediction parameters.
Data and product to generate sum for each delay
Then each correlation will have a different time delay.
Related, time correction is related to the correlation with the largest sum
It's a delay.

According to another feature of the invention, the radiotelephone includes a counter in the low speed clock and the step of generating the wakeup interrupt comprises the wakeup interrupt when the counter reaches a predetermined number. Including the step of generating According to another feature of the invention, one of the parameters of the pilot signal is a time offset, and the step of storing one or more parameters of the pilot signal comprises storing the time offset. including.

According to another feature of the invention, the step of calculating a prediction of the pilot signal comprises the step of calculating a prediction of a time offset of each pilot signal after the sleep period. The method may include weighting the time correction based on the signal strength of the reacquired pilot signal.

According to another feature of the invention, the step of weighting the time correction comprises weighting the time correction based on respective arrival times of the reacquired pilot signals, In that case,
Earlier arriving pilot signals are assigned more weight than later arriving pilot signals.

According to another feature of the invention, the step of adjusting the master timer comprises averaging the weighted time corrections and advancing or delaying the master timer by the amount of the time corrections. Adjusting the master timer.

According to another characteristic of the invention, the step of calculating a prediction parameter of the pilot signal after a sleep period comprises the step of basing the prediction on an internal factor of the radio telephone, in which case: The internal factors include the age of the low speed clock, the current state of the power supply voltage of the low speed clock, and the temperature of the low speed clock.

According to another characteristic of the invention, the step of calculating a prediction parameter of the pilot signal after a sleep period comprises the prediction of the movement of the radiotelephone, the arrival time of the reflected pilot signal, and the The step of basing on external factors of said wireless telephone, such as the course of the wireless telephone. According to another feature of the invention, the location and course of the radiotelephone can be measured by a global positioning system or based on the latitude and longitude of the transmitting base station. According to another feature of the invention, the master timer measures time in chips, and the step of adjusting the master timer comprises advancing or delaying the master timer one chip at a time.

According to another feature of the invention, a move to quickly reacquire a timing reference after a sleep period.
A station is disclosed, where the mobile station receives a pilot signal having multiple parameters from one or more base stations in a wireless network. The mobile station clocks a sleep period and a low speed clock configured to generate a wake-up interrupt at the end of the sleep period, a master timer configured to provide a timing reference for the mobile station , A digital signal processor configured to demodulate the pilot signal using the timing reference and determine parameters of the pilot signal. The mobile station further calculates a prediction of the parameter of the pilot signal after the sleep period based on the parameter determined by the digital signal processor, initiates the sleep period, and responds to the interrupt. Ending the sleep period, comparing the multiple correlation of the parameters of the pilot signal supplied by the digital signal processor with the prediction, and comparing the timing reference of the master timer with
A processor configured to adjust the master timer to align with the pilot signal based on the comparison of the multiple correlations .

According to another feature of the invention, the mobile station further comprises a memory for storing a history of the parameters of the pilot signal, the processor comprising: Based on the parameters determined by the digital signal processor, configured to calculate the prediction of the parameters of the pilot signal after the sleep period.

According to another feature of the invention, the processor turns on power to the slow clock before the sleep period and turns off power to the slow clock after the sleep period, It is configured to turn off power to the master timer at the beginning of a sleep period and turn on power to the master timer at the end of the sleep period.

According to yet another feature of the invention,
The master timer includes a counter and the processor is configured to adjust the master timer by speeding up or slowing down the counter. The mobile station further includes a fast timing reference operating at a multiple of the timing reference, and the processor is configured to speed up the master timer by advancing the counter according to the fast timing reference. Further, the processor is configured to adjust the master timer by slowing down the counter according to the timing reference.

According to another feature of the invention, the radiotelephone may include a global positioning system, in which case the processor determines the location of the mobile station ,
It is configured to calculate the prediction of the parameters of the pilot signal based on the position. Further, the processor may store a plurality of positions over time and calculate the prediction of parameters based on the stored positions.

Accordingly, it is an object of the present invention to provide a system that can quickly regain timing synchronization after a sleep mode. Another object of the present invention is to provide a system and method that minimizes power consumption while maintaining operability. Another object of the present invention is to provide a method for quickly reacquiring timing synchronization and maximizing sleep periods.

DETAILED DESCRIPTION A more complete understanding of the present invention can be obtained by considering the following detailed description in conjunction with the drawings. Sleep mode in wireless phones requires that the wireless phone can resynchronize to the timing of the wireless network as quickly as possible to maximize the benefits of sleep mode. For this purpose, a database of internal and external parameters that can affect slow (but energy efficient) clocks is maintained. Internal parameters include the age of the crystal source, the age of the battery, the ambient temperature, etc. External parameters are for pilot signals and for geography in general.
Including relative movement of the wireless telephone of the present invention. This radiotelephone has pilot signal parameters (eg time and frequency offset) at the end of sleep mode.
, Then shut down or shut down a number of internal devices (except the slow clock and sleep mode controllers). Upon exiting sleep mode, the radiotelephone re-acquires the pilot signal and resynchronizes the master timer by determining how far the prediction is from the reacquired current pilot signal.

FIG. 1 shows a block diagram of a wireless telephone, generally indicated at 10. At the heart of radiotelephone 10 is a microprocessor 12, which uses programs and data stored in memory 14 to coordinate, control, and operate radiotelephone 10. Microprocessor 12 also controls display 16 and keypad 18, which respectively display information to and receive input from the user.

Digital signal processor 20 includes a speaker and microphone (not shown here for clarity), as is known in the art.
A connection is made between the signal modulating / demodulating portion of the wireless telephone 10. Digital signal processor 20 coordinates its operation with a master timer 22, which in this exemplary embodiment includes a temperature compensated crystal oscillator. The master timer 22 increments the counter 24 by "chips" as the basic unit of time, as is known in the art. The signal from master timer 22 is provided to transmit modulator 26, searcher 28, and rake receivers 30, 32, and 34.

The transmission modulator 26 uses the ("spread code (sp
The known "access code" (obtained from the reading code), "long code", and other mobile-specific parameters) is used to represent data prepared by the digital signal processor 20 for a call to be transmitted. The symbol is modulated and the resulting signal is sent to a digital-to-analog converter (D / A) 36. In the reverse direction, an analog-to-digital converter (A / D) 38 provides a digital representation of the waveform to searcher receiver 28 and rake receivers 30, 32, and 34. The RF transceiver 40 sends and receives analog waveforms between the wireless telephone 10 and a wireless network (not shown, but known in the art) via an antenna 42.

In a typical RF communication system, the transmitted signal may travel from the transmitter to the receiver via multiple paths, eg, the direct path and also one or more reflected paths. Each path (which may be considered a separate “channel”) is subject to fading, Doppler shift, and so on. Moreover, the combination of channels at the receiver may cause additional fading.
The CDMA radiotelephone 10 is shown here as three rake receivers 30, 32, and 34.
More than one RAKE receiver is included, each demodulating the received channel. Rake receiver 30, 3
The outputs of 2 and 34 are constructively combined,
It is supplied to the digital signal processor 20. But,
In order to constructively combine their signals, the rake receivers 30, 32, and 34 must know the delay of their respective channels. (The two rake receivers are delayed to align when all three signals are combined.) In general, rake receivers 30, 32, and 34 work with searcher 28. The searcher 28 analyzes the received signal and determines some delayed versions of the signal of interest. The strongest channels are assigned to rake receivers 30, 32 and 34 and two delays are set.

In accordance with the present invention, sleep mode controller 50 operates with microprocessor 12, high speed clock source 52, and low speed clock source 54.
The high speed clock source 52 operates at a faster speed than the master timer 22 as is known in the art. The slow clock source 54 is less accurate than the oscillator in the master timer 22, as described further below,
Energy efficient.

An exemplary method of operation in the mobile station of FIG. 1 will now be described with reference to FIGS. 2 and 3. The process begins at circle 200, where mobile station 10
Signals such as pilot signals from one or more base stations are being actively demodulated. Processing is box 2
Moving to 02, an indication of the parameters of the pilot signal (complex vector describing the pilot signal) is stored in memory 14. Those parameters include frequency offset and timing offset,
It is not limited to these. To this end, the digital signal processor 20 identifies the searcher 28 to pilot signals from the server base station, pilot signals from surrounding neighboring base stations, and other previously identified at a given time offset. It is configured to perform a correlation search of the pilot signal. Digital signal processor 2
0 stores information in a database in memory 14.
In this way, pilot signal parameters representing the time offset and signal strength of the pilot signal and how the time offset and signal strength change with time are accumulated. The process then moves to decision diamond 204, where a determination is made whether sleep mode is possible. If sleep mode is not possible (ie, the mobile station is busy or receiving commands from the base station), the process returns to box 202.

If the microprocessor 12 determines at decision diamond 204 that sleep mode is possible, the process proceeds to box 206 where the microprocessor 12 sets an appropriate wake-up time for the wireless telephone 10. calculate. This data is loaded into sleep mode controller 50. In box 206, a prediction of the parameters of the pilot signal after the sleep mode has been completed, using the information stored in the database, the length of the sleep mode and other advantageous data, is used by the digital signal processor 20.
Calculated and stored. Such a calculation may be performed by extrapolation over a period in which the master time is in sleep mode, by determining how the frequency offset and other data changes over the sleep period, or It includes, but is not limited to, calculating further frequency offsets of pilot signals. Another one
One calculation may be for determining the timing offset of the one or more pilot signals at the end of the sleep period, the calculation of how the timing offset of the pilot signals changed over time. Is determined, and the change in the timing offset is extrapolated over the sleep mode period.
Similar calculations can be performed for other signal parameters.

Other data that may be used in the calculations include the crystal age of the slow clock source 54, the current battery age, the oscillator supply voltage, the unit temperature, and the known voltage / temperature condition / age. The previous calculation result in
Intrinsic factors including can be included. External factors that affect the timing of the pilot signal include movement of the wireless telephone. In addition, the proper location and course for the wireless telephone 10 can be estimated. This estimation is based on the wireless telephone 10
Arrival of signals based on an optional Global Positioning System (GPS) receiver in (not shown, but known in the art) or from several geographically well separated base stations Based on the change of time (in this case,
The latitude / longitude of the base station can be calculated, as is known in the art) (given by high level protocol messages). Further course and speed may be used to improve predictions. This is because the signal from the base station to which the wireless telephone 10 is heading arrives earlier in time, and the signal from the base station to which the wireless telephone 10 is heading away arrives later.

The process moves to action box 208 where microprocessor 12 starts low speed clock 54 which causes low speed clock 54 to sleep controller 5.
Allows to clock 0. Counter 56 is incremented at its rate of oscillation by low speed clock 54, as is known in the art. The microprocessor 12 then loads the wake-up time into the sleep controller 50. Microprocessor 12 also loads the prediction into master timer 22 (used in wake-up) and then turns off master timer 22. In action box 210, the microprocessor 12 turns off power to the high speed clock source 54. The microprocessor 12 then stops and waits for a wakeup interrupt. At block 212, the mobile station 10 is in sleep mode. Thus, in the sleep mode, the low speed clock source 54 and the counter 56 in the sleep mode control device 50.
Only powered and active.

Turning now to FIG. 3, sleep mode 2
The process after wakeup from 12 will be described. The timer has expired (sleep mode controller 22
When the interrupt 300 arrives from the sleep mode controller 50 to the microprocessor 12 after the counter 56 therein reaches a predetermined number), the process moves out of the sleep mode 212. The process moves to action box 302 where microprocessor 12 restarts master timer 22. The processor 12 also includes a searcher 28,
It also restarts rake receivers 30, 32, and 34, digital signal processor 20, and other components that were powered down or shut down during sleep mode. The fast clock source 52 is switched to replace the slow clock source 54. Parameters in CDMA that need to be re-initialized (ie, parameters that depend on the master timer 22) include:
The state of the orthogonal spreading sequence (short pseudo noise code),
Long pseudo-noise code state, frame timing,
Timing associated with the demodulation components of the rake receiver of the wireless telephone. The process moves to action box 304 where microprocessor 12 configures searcher 28 to perform a search to reacquire the pilot signal using previously stored parameters and restarted master timer 22. By doing so, the search is started.

Processing continues to action box 306 where, for each reacquired pilot signal, the digital signal processor 20 appears to best align the reacquired pilot signal with the prediction. Calculate the correction. The process moves to box 308 where, for each reacquired pilot signal, the digital signal processor 20 weights the calculated time correction based on:
That is, the signal strength of the reacquired pilot signal,
Weighting is based on its temporal position (greater weight is given to earlier than slower), stability before the slow clock 54, and the consistency of the location of the wireless telephone 10, thereby , The correction is biased so that stronger signals, stable clocks, etc. are emphasized. The process moves to action box 310 where digital signal processor 20 averages the weighted time corrections and adjusts master timer 22 with the weighted average time corrections by advancing or delaying the timers on a chip basis. The slide correlator 302 shown in FIG. 4 may be advantageously used for such calculations of boxes 306 and 308. The process ends at circle 312, where radiotelephone 10 is again actively demodulating the pilot and access channels.

The slide correlator 302 of FIG. 4 takes the newly received baseband signal sample on line 400 and applies the signal sample to delay line 402, as is known in the art. Delay tap 404
-1 through 404-X tap the baseband samples at various points on the delay line 402. These samples are then multiplied by multiplication taps 406-1 through 4-4.
At 06-X, for example, the predicted segment of the long code is multiplied. The product of the multiplication taps is the adder 40
At 8 the sums are added to generate the correlation. The speed at which long codes are multiplied can be increased or decreased and the master times are synchronized at the time of maximum correlation result.

Turning now to FIG. 5, a graph of signal strength versus time is shown. When the system exits sleep mode, it will move to locations 500, 502, and 5
At 04, the pilot signal is found. As shown in this example, the predicted correlation results 506, 508,
And 510 are behind in time with respect to the search results (from the searcher receiver 28). Also, the newly acquired pilot signal does not match the predicted parameters of the pilot signal (ie, shape, magnitude of signal strength, etc.). This reflects the fact that the signal is constantly changing for the wireless telephone 10. In the scenario of Figure 5, the timing prediction is corrected by advancing the system time until the actual correlation best matches the prediction. In this exemplary embodiment, the prediction is preferably behind the true system time after sleep mode. The speed with which time can be advanced is a function of the fastest clock (fast clock 52 in FIG. 1).
If the high speed clock 52 runs 12 times faster than the master timer 22, the time can be adjusted 12 times faster. If the above assumptions are made prior to system time, the correction can only be done at a rate of 1 chip per chip period.

It is therefore clear that the present invention provides a system that maximizes idle mode power down time. By predicting pilot signals at the end of the sleep period, the system can load these predictions and then quickly search and correlate those predictions with newly observed pilot data. The master timer can then be advanced or delayed depending on the observed pilot signal. It should be understood that many variations can be devised by those skilled in the art without departing from the scope of the invention. Such modifications are intended to fall within the scope of the appended claims. [Brief description of drawings]

FIG. 1 is a block diagram of a wireless telephone capable of quickly reacquiring a timing reference after sleep mode according to an exemplary embodiment of the present invention.

2 is a flowchart of the operation of the wireless telephone of FIG. 1 before a sleep mode.

FIG. 3 illustrates operation of the wireless telephone of FIG. 1 after sleep mode.

FIG. 4 shows the exemplary slide correlator of FIG.

FIG. 5 shows an example of predicted versus actual correlation results in timing reference reacquisition.

Continuation of front page (56) Reference JP-A-10-256984 (JP, A) (58) Fields investigated (Int.Cl. ⁷ , DB name) H04B 7/24-7/26 H04Q 7/00-7 / 38

Claims (39)

(57) [Claims] 1. A wireless telephone that escapes from a sleep period
A method of reacquiring a more timing reference,
Line phone receives a pilot signal having a plurality of parameters from one or more base stations in a wireless network, wireless phone, the was allowed to synchronize to a timing reference in the wireless network master timer (22) And low speed clock (54) and processor
And (12, 20), possess a memory (24), the said lateral <br/> method, and storing over time the parameters of one or more of the pilot signal, said stored calculating a predicted parameters of the pilot signals after the sleep period based on the parameter, turns off the power to the master timer (22), a step of stopping said processor (12, 20) Generating a wake-up interrupt in response to the low speed clock (54) after the sleep period; and the master timer in response to the wake-up interrupt.
Turning on power to (22) and processor (12, 20) ; reacquiring the pilot signal with a plurality of parameters from one or more base stations; and the received pilot signal. Of the pilot signal and the prediction parameter that best aligns the prediction parameter with the prediction parameter of the pilot signal.
Calculating according to multiple correlations with the received pilot signal; and adjusting the master timer (22) with the time correction. 2.The multiple correlation is a slide correlator (30
The method according to claim 1, which is performed using 2). 3. The master timer (22) is provided with the slave.
Related to the maximum correlation determined by the id correlator (302)
The adjustment according to claim 2, wherein the time correction is performed.
Method. 4. The slide phase for each correlation
A function (302) determines the prediction parameters for the received pilot signal samples.
Multiplying the data, and adds the product of the received pilot signal and the prediction parameters
Generate a sum for each delay, each correlation being associated with a different time delay,
Positive, at the delay associated with the correlation having the largest sum
There The method of claim 2. 5. The master timer(22)Power to
Turn off the slow clock before turning off(54)Power to
Turning on, the master timer(22)
The slow clock after turning on the power to(5
4)Turning off power to the
The method according to claim 1, wherein 6. The step of calculating said time correction comprises the step of weighting some of said time corrections of said received pilot signal in said calculation, said master timer (22) adjusting by said weighted time correction. The method of claim 1, wherein the method comprises: 7. The method of claim 1, wherein the slow clock (54) increments a counter and the sleep period ends when the counter reaches a predetermined number. 8. The method of claim 1, wherein one of the parameters of each pilot signal is a time offset and the step of storing one or more parameters comprises the step of storing the time offset. . It said step of 9. To calculate the prediction parameters of the pilot signal comprises the step of calculating a prediction of the time offset of each parameter signal in after the sleep period, the method of claim 8. 10. One of the parameters of the pilot signal
7. The method of claim 6 , wherein one comprises signal strength, and wherein the step of weighting the time correction comprises weighting the time correction based on the signal strength of the pilot signal. 11. The method of claim 6 , wherein the step of weighting the time correction is based on the arrival time of each reacquired pilot signal. The 12. reacquisition pilot signal arriving early, are assigned weights greater than reacquisition pilot signals arriving late, The method of claim 11. 13. The master timer (22) increments a counter and the step of adjusting the master timer (22) averages the weighted time corrections and adjusts the timing increment of the counter based on the average. 7. The method of claim 6 including the step of: 14. The method of claim 1, wherein the step of calculating a prediction of the pilot signal after a sleep period uses internal factors of the radiotelephone that affect the accuracy of the prediction parameter. 15. The internal factor is the slow clock (5
The method according to claim 14 , which comprises the age of 4) . 16. The internal factor is the low speed clock.
15. The method of claim 14 , including the current state of the power supply voltage of (54) . 17. The internal factor is the slow clock (5
15. The method of claim 14 including the temperature of 4) . 18. The internal factor is the low speed clock.
15. The method of claim 14 , including the previous calibration results of (54) at known voltage, temperature, and age conditions. 19. The method of claim 1, wherein the step of calculating a prediction of the parameter after a sleep period comprises using an external factor of the radiotelephone that affects the accuracy of the prediction parameter. 20. The method of claim 19 , wherein the external factor comprises movement of a wireless telephone. 21. The method of claim 19 , wherein the extrinsic factor comprises an arrival time of a reflected pilot signal. 22. The method of claim 19 , wherein the external factors include the location and course of the wireless telephone. 23. The method of claim 22 , wherein the wireless telephone includes a global positioning system, and the location and course of the wireless telephone are calculated by the global positioning system. 24. The parameters of the pilot signal include latitude and longitude of the base station, and the location and course of the radiotelephone are based on changes in arrival times of the pilot signal from several base stations. , Claims
22 . The method according to claim 25, wherein the master timer (22) is time measured in a chip unit, wherein the step of adjusting the master timer (22), the advancing or retarding step by the master timer (22) one chip increments The method of claim 1, comprising. 26. A timing reference is provided after the sleep period.
Reacquire quicklyMade mobile stationAt theTransfer
MotiveIs one or more groups in the wireless network.
A pilot signal with multiple parameters from the ground station
ReceiveTo be done, The aboveMobile stationBut the sleep period
To wake up at the end of the sleep period
Sleep controller configured to generate an interrupt
And the aboveMobile stationTo supply a timing reference for
Master timer configured in(22)And the timing
Demodulate the pilot signal using a reference and
Recovery configured to determine the parameters of the lot signal
Adjuster(20)When,A processor (12, 20)
The processor (12, 20) (A) Digital signal processor(12, 20)By
Based on the determined parameters, the sleep period
AfterPredicted ofThe parameters of the pilot signalTa
ToCalculate, (B) start the sleep period, (C) End the sleep period in response to the interrupt
Then (D) of pilot signalThe aboveThe parameterMultiple correlation ofTo
Compared to the prediction, (E)Based on the comparison of the multiple correlations,The master data
Imma(22)The timing reference of the pilot
The master timer to align with the signal(22)
Adjust, Is configured asIs characterized byThe aboveMobile station. 27. The processor (12, 20) comprises :
Note that the multiple correlation of the parameters of the pilot signal is
27. A slide correlator (302) for comparison is included.
The mobile station described in. 28. The processor (12, 20) comprises :
Maximum correlation determined by slide correlator (302)
The master timer (22) by the time correction related to
28. The method of claim 27, which is configured to adjust
Mobile station. 29. The slide for each correlation
A correlator (302) samples the received pilot signal with the prediction parameters.
Multiplying the data, and adds the product of the received pilot signal and the prediction parameters
Configured to generate the sum for each delay
Is, in relation to the respective correlator different time delays, and said processor (12, 20) is, before having the maximum sum
Using the delay associated with the correlation, the master timer
The time reference of (22) is added to the pilot signal.
Adjust the master timer (22) to turn it on.
28. The mobile station of claim 27 , configured as described above. 30. The mobile station according to claim 26 , further comprising a memory (24) for storing a history of the parameters of the pilot signal. 31. The processor (12, 20) further comprises the parameter of the pilot signal after the sleep period based on the parameter determined by the digital signal processor (12, 20) and the history of parameters. 31. The mobile station of claim 30 , configured to calculate a prediction of. 32. The processor (12, 20) further comprises the slow clock (54) prior to the sleep period.
27. The mobile station of claim 26 , configured to turn on power to and to turn off power to the slow clock (54) after the sleep period. 33. The move of claim 26 , wherein the sleep controller includes a counter and the sleep controller is configured to generate an interrupt in response to reaching a predetermined number of the counter. Station. 34. The mobile station of claim 33 , further comprising a low speed clock (54) coupled to the sleep controller that increments the counter. 35. The processor (1) further comprising a fast timing reference operating at a multiple of the timing reference.
2, 20) by advancing the master timer (22) according to the high speed timing reference.
Configured to speed up (22) ,
The mobile station according to claim 34 . 36. The mobile station of claim 34 , wherein the processor (12, 20) is configured to adjust the master timer (22) by slowing the master timer (22) . 37. A global positioning system is further included, wherein the processor (12, 20) is configured to determine a position of the mobile station and further based on the position the prediction of the parameter of the pilot signal. 27. The mobile station of claim 26 , configured to calculate 38. The processor (12,20) is configured to store the determined and the position of the plurality of the plurality of positions over time, said processor (12, 2
0) is further based on the stored plurality of positions,
38. The mobile station of claim 37 , configured to calculate the prediction of the parameter of the pilot signal. 39. The processor (12, 20) further comprises the master timer (2 ) at the start of the sleep period.
2) is configured to turn off power to 2) and turn on power to the master timer (22) in response to the interrupt at the end of the sleep period.
The mobile station according to 26 .